Image sensor with improved timing resolution and photon detection probability

ABSTRACT

In some embodiments, a photodetector is provided. The photodetector includes a first well having a first doping type disposed in a semiconductor substrate. A second well having a second doping type opposite the first doping type is disposed in the semiconductor substrate on a side of the first well. A first doped buried region having the second doping type is disposed in the semiconductor substrate, where the first doped buried region extends laterally through the semiconductor substrate beneath the first well and the second well. A second doped buried region having the second doping type is disposed in the semiconductor substrate and vertically between the first doped buried region and the first well, where the second doped buried region contacts the first well such that a photodetector p-n junction exists along the second doped buried region and the first well.

REFERENCE TO RELATED APPLICATION

This Application claims the benefit of U.S. Provisional Application No.62/733,970, filed on Sep. 20, 2018, the contents of which are herebyincorporated by reference in their entirety.

BACKGROUND

Many modern day electronic devices (e.g., smartphones, digital cameras,biomedical imaging devices, automotive imaging devices, etc.) compriseimage sensors. The image sensors comprise one or more photodetectors(e.g., photodiodes, phototransistors, photoresistors, etc.) configuredto absorb incident radiation and output electrical signals correspondingto the incident radiation. Some types of image sensors includecharge-coupled device (CCD) image sensors and complementarymetal-oxide-semiconductor (CMOS) image sensors. Compared to CCD imagesensors, CMOS image sensors are favored due to low power consumption,small size, fast data processing, a direct output of data, and lowmanufacturing cost. Some types of CMOS image sensors include front-sideilluminated (FSI) image sensors and backside illuminated (BSI) imagesensors.

BRIEF DESCRIPTION OF THE DRAWINGS

Aspects of the present disclosure are best understood from the followingdetailed description when read with the accompanying figures. It isnoted that, in accordance with the standard practice in the industry,various features are not drawn to scale. In fact, the dimensions of thevarious features may be arbitrarily increased or reduced for clarity ofdiscussion.

FIG. 1 illustrates a cross-sectional view of some embodiments of acomplementary metal-oxide-semiconductor (CMOS) image sensor.

FIG. 2 illustrates a cross-sectional view of some more detailedembodiments of the CMOS image sensor of FIG. 1.

FIG. 3 illustrates a cross-sectional view of some alternativeembodiments of the CMOS image sensor of FIG. 2.

FIGS. 4-15 illustrate a series of cross-sectional views of someembodiments of a method for forming the CMOS image sensor of FIG. 3.

FIG. 16 illustrates a flowchart of some embodiments of a method forforming the CMOS image sensor of FIG. 3.

DETAILED DESCRIPTION

The present disclosure will now be described with reference to thedrawings wherein like reference numerals are used to refer to likeelements throughout, and wherein the illustrated structures are notnecessarily drawn to scale. It will be appreciated that this detaileddescription and the corresponding figures do not limit the scope of thepresent disclosure in any way, and that the detailed description andfigures merely provide a few examples to illustrate some ways in whichthe inventive concepts can manifest themselves.

The present disclosure provides many different embodiments, or examples,for implementing different features of this disclosure. Specificexamples of components and arrangements are described below to simplifythe present disclosure. These are, of course, merely examples and arenot intended to be limiting. For example, the formation of a firstfeature over or on a second feature in the description that follows mayinclude embodiments in which the first and second features are formed indirect contact, and may also include embodiments in which additionalfeatures may be formed between the first and second features, such thatthe first and second features may not be in direct contact. In addition,the present disclosure may repeat reference numerals and/or letters inthe various examples. This repetition is for the purpose of simplicityand clarity and does not in itself dictate a relationship between thevarious embodiments and/or configurations discussed.

Further, spatially relative terms, such as “beneath,” “below,” “lower,”“above,” “upper” and the like, may be used herein for ease ofdescription to describe one element or feature's relationship to anotherelement(s) or feature(s) as illustrated in the figures. The spatiallyrelative terms are intended to encompass different orientations of thedevice in use or operation in addition to the orientation depicted inthe figures. The apparatus may be otherwise oriented (rotated 90 degreesor at other orientations) and the spatially relative descriptors usedherein may likewise be interpreted accordingly.

Some complementary metal-oxide-semiconductor (CMOS) image sensorscomprise a single-photon avalanche diode (SPAD) disposed in asemiconductor substrate. The SPAD is a photodetector configured toabsorb incident radiation (e.g., near-infrared radiation) and outputelectrical signals having a relatively large avalanche current comparedto an amount of photo-generated charge carriers created in thephotodetector (e.g., due to absorbing a photon). The SPAD comprises apair of first wells having a first doping type (e.g., n-type doping)disposed in the semiconductor substrate. A second well having a seconddoping type (e.g., p-type doping) opposite the first doping type isdisposed in the semiconductor substrate between the first wells. A dopedburied layer is disposed in the semiconductor substrate below the secondwell and extends between the first wells. The second well contacts thedoped buried layer in a vertical direction between the first wells.Thus, a p-n junction exists between the second well and the doped buriedlayer. Accordingly, a depletion region is formed (e.g., due to the p-njunction between the second well and the doped buried layer) along thesecond well and the doped buried layer.

One challenge with the CMOS image sensors is photon detectionprobability (PDP). For a CMOS image sensor comprising a near-infraredSPAD (NIR-SPAD), PDP is the probability that the NIR-SPAD willsuccessful detect (e.g., output an electrical signal) a given input(e.g., about a single photon) propagating through space at near-infrared(NIR) wavelengths (e.g., between about 750 nanometers (nm) and about 2.5micrometers (μm)). One possible solution to improve the PDP of theNIR-SPAD is to arrange the p-n junction between the second well and thedoped buried region deeper in the semiconductor substrate (e.g., spacedfurther away from a surface of the semiconductor substrate) than in ashallow p-n junction NIR-SPAD (e.g., a NIR-SPAD having a p-n junctiondisposed near the surface of the semiconductor substrate).

Due to NIR radiation penetrating deeper into the semiconductor substrateand having a higher impact ionization rate (e.g., due to the wavelengthsof NIR radiation), a p-n junction disposed deeper in the semiconductorsubstrate may improve the PDP of the NIR-SPAD due to the depletionregion of the NIR-SPAD being arranged in a portion of the semiconductorsubstrate having a higher probability of photo-generated charge carrierstransporting to the depletion region. Accordingly, the CMOS image sensormay have improved PDP. However, by arranging the p-n junction betweenthe second well and the doped buried region deeper in the semiconductorsubstrate, timing resolution of the CMOS image sensor may be negativelyaffected.

For a CMOS image sensor comprising a NIR-SPAD, timing resolution is thestatistical uncertainty that occurs when measuring the electrical signaloutput by the NIR-SPAD. For example, if timing resolution was zero, eachelectrical signal output by the NIR-SPAD would be output at an expectedoutput signal time based on the time a photo-generated charge carrier iscreated in the NIR-SPAD. One factor that negatively affects timingresolution is that a photo-generated charge carrier may be created atvarying locations in the semiconductor substrate between a top of thesecond well and the doped buried layer. The time it takes for thephoto-generated charge carrier to transport from the varying locationsto the depletion region is directly proportional to the distance inwhich the photo-generated charge carrier is created from the depletionregion. Depending on where the photo-generated charge carrier is created(e.g., in the depletion region, near the depletion region, or relativelyfar from the depletion region), the NIR-SPAD may output an electricalsignal that deviates (e.g., occurs before or after) from the expectedoutput signal time. Accordingly, as the p-n junction is arranged deeperin the semiconductor substrate, performance of the CMOS image sensor maydegrade due to timing resolution because of a maximum distance from thedepletion region in which the NIR-SPAD may detect a given input signal(e.g., about a single photon) increasing.

In various embodiments, the present application is directed toward aCMOS image sensor having a second doped buried region having a firstdoping type disposed between a first doped buried region having thefirst doping type and a first well having a second doping type oppositethe first doping type. The first well is disposed in a semiconductorsubstrate. The first doped buried region is disposed in thesemiconductor substrate beneath the first well. The second doped buriedregion is disposed in the semiconductor substrate between the firstwell. The second doped buried region contacts the first well.

Because the second doped buried region contacts the first well and hasan opposite doping type than the first well, a p-n junction existsbetween the second doped buried region and the first well. Thus, adepletion region is formed along the second doped buried region and thefirst well. Because the depletion region is disposed along the seconddoped buried region and the first well, the depletion region is morecentrally disposed in the semiconductor substrate between the firstdoped buried layer and a top of the first well, yet may still bedisposed deeper in the semiconductor substrate than in a CMOS imagesensor having a shallow p-n junction NIR-SPAD. The CMOS image sensor ofthe present application may have improved PDP over the CMOS image sensorhaving the shallow p-n junction NIR-SPAD due to the depletion regionbeing disposed deeper in the semiconductor substrate than in the CMOSimage sensor having the shallow p-n junction NIR-SPAD. Further, varyinglocations in which a photo-generated charge carrier may be created maybe more evenly spaced in/from the depletion region because the depletionregion is more centrally disposed in the semiconductor substrate betweenthe first doped buried layer and a top of the first well. Thus, the CMOSimage sensor of the present application may have improved timingresolution due to the time it takes for the photo-generated chargecarrier to transport from the varying locations to the depletion regionbeing more uniform.

FIG. 1 illustrates a cross-sectional view of some embodiments of acomplementary metal-oxide-semiconductor (CMOS) image sensor 100 having asecond doped buried region having a first doping type disposed between afirst doped buried region having the first doping type and a first wellhaving a second doping type opposite the first doping type.

As shown in FIG. 1, the CMOS image sensor 100 comprises a semiconductorsubstrate 102. In some embodiments, the semiconductor substrate 102 maycomprise any type of semiconductor body (e.g., monocrystallinesilicon/CMOS bulk, silicon-germanium (SiGe), silicon on insulator (SOI),etc.).

A pair of first wells 104 are disposed in the semiconductor substrate102. The first wells 104 are laterally spaced from one another andrespectively extend into the semiconductor substrate 102 from a firstside of the semiconductor substrate 102. In some embodiments, the firstwells 104 are regions of the semiconductor substrate 102 comprising afirst doping type (e.g., n-type doping). In some further embodiments,the first wells 104 may be a single well that is ring-shaped as viewedfrom above.

A pair of first electrodes 106 are disposed in the semiconductorsubstrate 102. The first electrodes 106 are disposed in the first wells104, respectively. In some embodiments, the first electrodes 106 areregions of the semiconductor substrate 102 comprising the first dopingtype (e.g., n-type doping). In further embodiments, the first electrodes106 have a higher concentration of the first doping type than the firstwells 104. In yet further embodiments, the first electrodes 106 may becathodes.

A second well 108 is disposed in the semiconductor substrate 102 betweenthe first wells 104. In some embodiments, the second well 108 is aregion of the semiconductor substrate 102 comprising a second dopingtype (e.g., p-type doping) opposite the first doping type. In furtherembodiments, the second well 108 extends into the semiconductorsubstrate from the first side of the semiconductor substrate 102. In yetfurther embodiments, the first wells 104 may be respectively spaced fromthe second well 108 on opposite sides of the second well 108. In suchembodiments, lightly-doped regions 109 may respectively separate thefirst wells 104 from the second well 108. In some embodiments, thelightly-doped regions 109 are regions of the semiconductor substrate 102comprising the second doping type (e.g., p-type doping). In furtherembodiments, the lightly-doped regions 109 have a lower concentration ofthe second doping type than the second well 108. In other embodiments,the lightly-doped regions 109 are intrinsic regions (e.g., undoped) ofthe semiconductor substrate 102.

A second electrode 110 is disposed in the second well 108. In someembodiments, the second electrode 110 is a region of the semiconductorsubstrate 102 comprising the second doping type (e.g., p-type doping).In further embodiments, the second electrode 110 has a higherconcentration of the second doping type than the second well 108. In yetfurther embodiments, the second electrode 110 may be an anode.

A first doped buried region 112 is disposed in the semiconductorsubstrate 102 beneath the first wells 104 and the second well 108. Insome embodiments, the first doped buried region 112 is a region of thesemiconductor substrate 102 comprising the first doping type (e.g.,n-type doping). In further embodiments, the first doped buried region112 is vertically spaced from the first wells 104 and the second well108. In yet further embodiments, the first doped buried region 112laterally extends through the semiconductor substrate 102 beneath thefirst wells 104 and the second well 108.

In some embodiments, the first doped buried region 112 is disposed overa semiconductor region 113. In some embodiments, the semiconductorregion 113 is a region of the semiconductor substrate 102 comprising thesecond doping type (e.g., p-type doping). In further embodiments, thesemiconductor region 113 has a lower concentration of the second dopingtype than the second well 108. In yet further embodiments, thesemiconductor region 113 has a substantially similar concentration ofthe second doping type as the lightly-doped regions 109. In otherembodiments, the semiconductor region 113 is an intrinsic region (e.g.,undoped) of the semiconductor substrate 102.

A second doped buried region 114 is disposed in the semiconductorsubstrate 102 between the first doped buried region 112 and the secondwell 108. In some embodiments, the second doped buried region 114 is aregion of the semiconductor substrate 102 comprising the first dopingtype (e.g., n-type doping). In some embodiments, the second doped buriedregion 114 has a different concentration of the first doping type thanthe first doped buried region 112. In further embodiments, the seconddoped buried region 114 has a lower concentration of the first dopingtype than the first doped buried region 112. In yet further embodiments,the second doped buried region 114 laterally extends through thesemiconductor substrate 102 over the first doped buried region 112 andbeneath the first wells 104 and the second well 108.

In yet further embodiments, the second doped buried region 114 contactsthe first doped buried region 112, the first wells 104, and the secondwell 108. Because the second doped buried region 114 has a differentdoping type than the second well 108 and contacts the second well 108, ap-n junction exists between the second doped buried region 114 and thesecond well 108. Thus, a depletion region 116 having a built-in electricfield forms along the second well 108 and the second doped buried region114.

In some embodiments, a photodetector 118 comprises the first wells 104,the second well 108, and the second doped buried region 114. Thephotodetector 118 is configured to absorb incident radiation 120 (e.g.,photons) and to output electrical signals corresponding to the incidentradiation. In some embodiments, the photodetector 118 is configured toabsorb incident radiation 120 having near infrared (NIR) wavelengths(e.g., between about 750 nanometers (nm) and about 2.5 micrometers(μm)). In some embodiments, the photodetector 118 may be, for example, aphotodiode, a phototransistor, a photoresistor, or the like. Morespecifically, in some embodiments, the photodetector 118 may be, forexample, an avalanche photodiode (APD) or a single-photon avalanchephotodiode (SPAD).

In some embodiments, during operation of the CMOS image sensor 100, anexternal reverse bias greater than an avalanche breakdown voltage of thephotodetector 118 is applied to the photodetector 118 (e.g., by applyinga positive voltage to the first electrode(s) 106 and a negative voltageto the second electrode 110). As the photodetector 118 absorbs incidentradiation 120 (e.g., photons), photo-generated charge carriers may beformed at varying locations L_(A)-L_(D) throughout the photodetector118. In some embodiments, the varying locations L_(A)-L_(D) comprise afirst location L_(A), a second location L_(B), a third location L_(C),and a fourth location L_(D). In further embodiments, if a distancebetween a top of the first doped buried region 112 and a top surface ofthe semiconductor substrate 102 is x, the first location L_(A) may bedisposed about 0.01× to about 0.45× from the top surface of thesemiconductor substrate 102, the second location L_(B) may be disposedabout 0.46× to about 0.57× from the top surface of the semiconductorsubstrate 102, the third location L_(C) may be disposed about 0.58× toabout 0.86× from the top surface of the semiconductor substrate 102, andthe fourth location L_(D) may be disposed about 0.87× to about 0.97×from the top surface of the semiconductor substrate 102. In yet furtherembodiments, the distance between a top of the first doped buried region112 and a top surface of the semiconductor substrate 102 may be betweenabout 2.5 μm and about 4.5 μm.

In some embodiments, due to the external reverse bias applied to thephotodetector 118 being greater than the avalanche breakdown voltage, asingle photo-generated charge carrier (e.g., due to the photodetector118 absorbing a photon) may transport from one of the varying locationsL_(A)-L_(D) to the depletion region 116 causing the photodetector 118 tooutput an electrical signal having an avalanche current. In someembodiments, the photodetector 118 outputs the electrical signal havingthe avalanche current because of the built-in electric field of thedepletion region 116 sweeping the photo-generated charge carrier awayfrom the p-n junction between the second doped buried region 114 and thesecond well 108, such that a self-sustaining avalanche is triggered. Infurther embodiments, the photodetector 118 may output the electricalsignal to a quenching circuit (not shown) (e.g., passive or active)configured to sense the electrical output and restore the photodetector118 to its pre-electrical signal output operating condition.

Because the second doped buried region 114 is disposed between thesecond well 108 and the first doped buried region 112 and contacts thesecond well 108, the depletion region 116 (e.g., formed due to the p-njunction between the second well 108 and the second doped buried region114) may be formed about mid-way between a bottom of the secondelectrode 110 and the top of the first doped buried region 112. Becausethe depletion region 116 forms about mid-way between the bottom of thesecond electrode 110 and the top of the first doped buried region 112,the first location L_(A) and the fourth location L_(D) are about evenlyspaced from the depletion region 116. Thus, the time it takes for aphoto-generated charge carrier to transport from the first locationL_(A) or the fourth location L_(D) to the depletion region is about thesame. Accordingly, timing resolution of the CMOS image sensor 100 may beimproved. Further, because the depletion region is disposed along thesecond doped buried region 114 and the second well 108, the depletionregion 116 may be disposed deeper in the semiconductor substrate 102than in a CMOS image sensor having a shallow p-n junction NIR-SPAD(e.g., a NIR-SPAD having a p-n junction disposed near the surface of thesemiconductor substrate). Accordingly, the CMOS image sensor 100 mayhave improved photo detection probability (PDP) over the CMOS imagesensor having the shallow p-n junction NIR-SPAD due to the depletionregion 116 being disposed deeper in the semiconductor substrate 102 thanin the CMOS image sensor having the shallow p-n junction NIR-SPAD.

FIG. 2 illustrates a cross-sectional view of some more detailedembodiments of the CMOS image sensor of FIG. 1.

As shown in FIG. 2, the second well 108 is disposed in the semiconductorsubstrate 102 between the first wells 104. In some embodiments, oppositesides of the second well 108 may be laterally spaced by about 4 μm toabout 18 μm. In some embodiments, the second doped buried region 114 isdisposed between the first doped buried region 112 and the second well108. In further embodiments, the first doped buried region 112 has ahigher concentration of the first doping type than the second dopedburied region 114. In yet further embodiments, the second doped buriedregion 114 has a higher concentration of the first doping type than thefirst wells 104.

A pair of third wells 202 are disposed in the semiconductor substrate102. The third wells 202 are regions of the semiconductor substrate 102having the first doping type (e.g., n-type doping). In some embodiments,the third wells 202 are disposed in the first wells 104, respectively.In some embodiments, the third wells 202 respectively separate the firstelectrodes 106 from the first wells 104. In some embodiments, the thirdwells 202 are respectively separated from the second doped buried region114 by the first wells 104. In further embodiments, the third wells 202have a higher concentration of the first doping type than the firstwells 104. In yet further embodiments, the third wells 202 have a lowerconcentration of the first doping type than the first electrodes 106.

A pair of first pick-up wells 204 are disposed in the semiconductorsubstrate 102. The pick-up wells 204 are regions of the semiconductorsubstrate 102 having the second doping type (e.g., p-type doping). Insome embodiments, the first pick-up wells 204 are configured to providea bias to the semiconductor substrate 102. In further embodiments, thefirst wells 104 separate the first pick-up wells 204 from the secondwell 108, respectively. In further embodiments, the first pick-up wells204 are each laterally spaced from the second well 108. In yet furtherembodiments, the lightly-doped regions 109 have a lower concentration ofthe second doping type than the first pick-up wells 204.

In some embodiments, bottoms of the first pick-up wells 204 may bedisposed below bottoms of the first wells 104, respectively. In furtherembodiments, the bottoms of the first pick-up well 204 may be disposedbetween a bottom of the first doped buried region 112 and a top of thefirst doped buried region 112. In some embodiments, the first pick-upwells 204 may contact the first wells 104, respectively. In furtherembodiments, the first pick-up wells 204 may also contact the firstdoped buried region 112 and the second doped buried region 114. In suchembodiments, sides of the first pick-up wells 204 facing the second well108 may respectively contact the second doped buried region 114 and thefirst doped buried region 112 below the bottoms of the first wells 104and respectively contact the first wells 104 above the bottoms of thefirst wells 104.

A pair of second pick-up wells 206 are disposed in the semiconductorsubstrate 102. The second pick-up wells 206 are regions of thesemiconductor substrate 102 having the second doping type (e.g., p-typedoping). In some embodiments, the second pick-up wells 206 are disposedin the first pick-up wells 204, respectively. In further embodiments,the second pick-up wells 206 have a higher concentration of the seconddoping type than the first pick-up wells 204. In yet furtherembodiments, the first pick-up wells 204 respectively separate thesecond pick-up wells 206 from the first wells 104.

A pair of pick-up well contacts 208 are disposed in the semiconductorsubstrate 102. The pick-up well contacts 208 are regions of thesemiconductor substrate 102 having the second doping type (e.g., p-typedoping). In some embodiments, the pick-up well contacts 208 are disposedin the second pick-up wells 206, respectively. In some embodiments, thesecond pick-up wells 206 may separate the pick-up well contacts 208 fromthe first pick-up wells 204, respectively. In further embodiments, thepick-up well contacts 208 may have a higher concentration of the seconddoping type than the second pick-up wells 206. In yet furtherembodiments, silicide structures (not shown) may be disposed on thepick-up well contacts 208.

A plurality of isolation structures 210 are disposed in thesemiconductor substrate 102. The isolation structures 210 may, forexample, be a shallow trench isolation (STI) structure, a deep trenchisolation (DTI) structure, or the like. In some embodiments, some of theisolation structures 210 are disposed between the first electrodes 106and the first pick-up well contacts 208, respectively. In someembodiments, portions of the first wells 104, the third wells 202, thefirst pick-up wells 204, the second pick-up wells 206, the first dopedburied region 112, and/or the second doped buried region 114 may bedirectly disposed beneath the some of the isolation structures 210. Insuch embodiments, the first wells 104 may contact the first pick-upwells 204 beneath the some of the isolation structures 210. In furthersuch embodiments, sides of the some of the isolation structures 210 maybe laterally spaced from sides of the first wells 104 by about 0.2 μm toabout 1.0 μm. In further such embodiments, the first doped buried region112 and/or the second doped buried region 114 may contact the firstpick-up wells 204 beneath the some of the isolation structures 210. Insome embodiments, some other of the isolation structures 210 arerespectively disposed on sides of the first pick-up well contacts 208opposite the second well 108. In such embodiments, portions of the firstpick-up wells 204 and/or the second pick-up wells 206 may be directlydisposed beneath the some of the isolation structures 210.

An interlayer dielectric (ILD) layer 212 is disposed over thesemiconductor substrate 102, the first wells 104, the second well 108,and the first pick-up wells 204. In some embodiments, the ILD layer 212may have a substantially planar upper surface. In further embodiments,the ILD layer 212 comprises one or more of a low-k dielectric layer(e.g., a dielectric with a dielectric constant less than about 3.9), anultra-low-k dielectric layer, an oxide (e.g., SiO₂), or the like.Further, a plurality of conductive contacts 214 are disposed in the ILDlayer 212. In some embodiments, the conductive contacts 214 extendthrough the ILD layer 212 to respectively contact the first electrodes106, the second electrode 110, and/or the pick-up well contacts 208.

An inter-metal dielectric (IMD) layer 216 is disposed on the ILD layer212 and the conductive contacts 214. In some embodiments, the IMD layer216 comprises one or more of a low-k dielectric layer, an ultra-low-kdielectric layer, an oxide, or the like. Further, a plurality ofconductive features 218 (e.g., conductive lines and/or conductive vias)are disposed in the IMD layer 216. In some embodiments, multiple IMDlayers 216 may be stacked on the ILD layer 212, and additionalconductive features 218 may be disposed in each of the multiple IMDlayers 216. In such embodiments, about 4 to about 10 IMD layers 216 maybe stacked on the ILD layer 212 to reduce light attenuation caused bythe multiple IMD layers 216 and the conductive features 218 respectivelydisposed in the multiple IMD layers 216.

A passivation layer 220 is disposed over the IMD layer 216 and theconductive features 218. In some embodiments, the passivation layer 220may comprise, for example, an oxide, a nitride, an oxy-nitride, apolymer, or the like. In further embodiments, an interconnect structure222 may comprise the ILD layer 212, the conductive contacts 214, the IMDlayer 216, the conductive features 218, and the passivation layer 220.In yet further embodiments, the interconnect structure 222 is configuredto provide electrical connections between various devices disposedthroughout the CMOS image sensor 100.

FIG. 3 illustrates a cross-sectional view of some alternativeembodiments of the CMOS image sensor of FIG. 2.

As shown in FIG. 3, the semiconductor substrate 102 comprises anepitaxial structure 302 disposed on a first semiconductor material layer304. In some embodiments, the first semiconductor material layer 304comprises a crystalline semiconductor material (e.g., monocrystallinesilicon wafer, silicon, gallium-arsenide wafer, etc.). In someembodiments, the first semiconductor material layer 304 is intrinsic(e.g., undoped). In other embodiments, the first semiconductor materiallayer 304 may comprise the second doping type (e.g., p-type doping). Insome embodiments, the epitaxial structure 302 comprises the seconddoping type. In some embodiments, epitaxial structure regions 305separate the first wells 104 from the second well 108. In otherembodiments, the epitaxial structure 302 may be intrinsic. In furtherembodiments, the epitaxial structure 302 may have a resistivity betweenabout 6 ohm-centimeter and about 14 ohm-centimeter. In yet furtherembodiments, the epitaxial structure 302 may have a thickness betweenabout 3 μm and about 7 μm.

In some embodiments, the second doped buried region 114 is disposed inboth the epitaxial structure 302 and the first semiconductor materiallayer 304. In some embodiments, the first doped buried region 112 isdisposed in the first semiconductor material layer 304. In furtherembodiments, the first wells 104, the third wells 202, the firstelectrodes 106, the first pick-up wells 204, the second pick-up wells206, the pick-up well contacts 208, the isolation structures 210, thesecond well 108, and the second electrode 110 are disposed in theepitaxial structure 302. In yet further embodiments, a bottom of thesecond doped buried region 114 is disposed below the bottoms of thefirst pick-up wells 204.

In some embodiments, the isolation structures 210 respectively compriseisolation structure liners 306 and isolation structure dielectrics 308.The isolation structure dielectrics 308 are respectively disposed on theisolation structure liners 306. In some embodiments, the isolationstructure liners 306 respectively separate the isolation structuredielectrics 308 from the epitaxial structure 302. In furtherembodiments, the isolation structure liners 306 may comprise, forexample, a nitride, an oxide, an oxy-nitride, or the like. In yetfurther embodiments, the isolation structure dielectrics 308 maycomprise an oxide (e.g., SiO₂).

In some embodiments, a micro-lens 310 is disposed on the passivationlayer 220. The micro-lens is configured to focus incident radiation(e.g., photons) towards the photodetector 118. In other embodiments, themicro-lens 310 may be disposed on a back-side (e.g., on a side of thesemiconductor substrate 102 opposite a side of the semiconductorsubstrate 102 in which the interconnect structure 222 is disposed) ofthe semiconductor substrate 102.

FIGS. 4-15 illustrate a series of cross-sectional views of someembodiments of a method for forming the CMOS image sensor of FIG. 3.

As shown in FIG. 4, a first doped buried region 112 is formed in a firstsemiconductor material layer 304. The first doped buried region 112 is aregion of the first semiconductor material layer 304 comprising a firstdoping type (e.g., n-type doping). In some embodiments, the first dopedburied region 112 may be formed by a first selective ion implantationprocess that utilizes a masking layer (not shown) to selectively implantions into the first semiconductor material layer 304.

In some embodiments, the first selective ion implantation utilized toform the first doped buried region 112 may comprise implanting a dosageof antimony ions between about 5.0×10¹⁴ ions/cm² and about 5.0×10¹⁵ions/cm² into the first semiconductor material layer 304 at an ionenergy between about 50 kiloelectron volts (keV) and about 150 keV. Insome embodiments, the first selective ion implantation utilized to formthe first doped buried region 112 may also comprise implanting a dosageof phosphorous ions between about 1.0×10¹³ ions/cm² and about 1.0×10¹⁵ions/cm² into the first semiconductor material layer 304 at an ionenergy between about 30 keV and about 100 keV. In further embodiments, afirst drive-in anneal (e.g., rapid thermal anneal (RTA), furnace anneal,etc.) may be performed on the first semiconductor material layer 304 toactivate the ions implanted by the first selective ion implantation. Inyet further embodiments, the first drive-in anneal may comprise heatingthe first semiconductor material layer 304 in a nitrogen gas (N₂)environment to a temperature between about 900° C. and about 1200° C.for about 30 minutes to about 130 minutes.

As shown in FIG. 5, an initial doped layer 502 is formed in the firstsemiconductor material layer 304 and over the first doped buried region112. The initial doped layer 502 is a region of the first semiconductormaterial layer 304 comprising the first doping type (e.g., n-typedoping). In some embodiments, the initial doped layer 502 is formed witha lower concentration of the first doping type than the first dopedburied region 112. In some embodiments, the initial doped layer 502 maybe formed by a second selective ion implantation process 504 thatutilizes a masking layer (not shown) to selectively implant ions intothe first doped buried region 112. In further embodiments, the secondselective ion implantation process 504 may comprise implanting a dosageof phosphorous ions between about 5.0×10¹³ ions/cm² and about 1.0×10¹⁵ions/cm² into the first doped buried region 112 at an ion energy betweenabout 20 keV and about 100 keV.

As shown in FIG. 6, an epitaxial structure 302 is formed on the firstsemiconductor material layer 304 and the initial doped layer 502. Insome embodiments, the epitaxial structure 302 may formed with aresistivity between about 6 ohm-centimeter and about 14 ohm-centimeter.In some embodiments, the epitaxial structure 302 may have a thicknessbetween about 3 μm and about 7 μm. In further embodiments, the epitaxialstructure 302 may be formed by, for example, vapor-phase epitaxy (VPE),molecular-beam epitaxy (MBE), liquid-phase epitaxy (LPE), solid-phaseepitaxy (SPE), reduced pressure chemical vapor deposition (RP-CVD)epitaxy, metalorganic vapor phase epitaxy (MOVPE), or the like. In yetfurther embodiments, a planarization process (e.g., achemical-mechanical planarization (CMP)) may be performed on an uppersurface of the epitaxial structure 302 to form a planar upper surface.In some embodiments, a semiconductor substrate 102 comprises theepitaxial structure 302 and the first semiconductor material layer 304

As shown in FIG. 7, a plurality of trenches 702 are formed in theepitaxial structure 302. In some embodiments, the trenches 702 arelaterally spaced and respectively extend into the epitaxial structure302 from a first side of the epitaxial structure 302. In someembodiments, some of the trenches 702 at least partially overlap thefirst doped buried region 112 in a vertical direction.

In some embodiments, a process for forming the trenches 702 comprisesperforming an etch (e.g., a dry etch and/or a wet etch) into theepitaxial structure 302. In some embodiments, the etch may be performedwith an isolation structure patterning stack 704 formed on the epitaxialstructure 302. In some embodiments, the isolation structure patterningstack 704 may comprise a nitride layer disposed over the epitaxialstructure 302 and a masking layer disposed on the nitride layer. Theepitaxial structure 302 is then exposed to one or more etchant(s) thatremove portions of the nitride layer of the isolation structurepatterning stack 704 and the epitaxial structure 302 not covered by themasking layer to form the trenches 702. Subsequently, the masking layerof the isolation structure patterning stack 704 may be removed. In yetfurther embodiments, one or more deposition process(es) (e.g., chemicalvapor deposition (CVD), physical vapor deposition (PVD), atomic layerdeposition (ALD), thermal oxidation, sputtering, etc.) may be utilizedto form the isolation structure patterning stack on the epitaxialstructure 302.

Also shown in FIG. 7, isolation structure liners 306 are respectivelyformed lining the trenches 702. The isolation structure liners 306 maycomprise, for example, a nitride, an oxide, an oxy-nitride, or the like.In some embodiment, the isolation structure liners 306 may be depositedand/or grown on the epitaxial structure 302 by, for example, thermaloxidation, CVD, PVD, ALD, sputtering, or the like. In some embodiments,after the isolation structure liners 306 are respectively formed in thetrenches 702, an isolation structure liner anneal 706 (RTA, furnaceanneal, etc.) may be performed on the semiconductor substrate 102 toreduce defects at an interface between the isolation structure liners306 and the epitaxial structure 302. In further embodiments, theisolation structure anneal 706 may comprise heating the semiconductorsubstrate 102 to a temperature between about 900° C. and about 1200° C.for about 200 minutes to about 300 minutes. In yet further embodiments,the isolation structure liner anneal 706 also diffuses ions of theinitial doped layer 502 into the epitaxial structure 302 to form thesecond doped buried region 114.

As shown in FIG. 8, isolation structure dielectrics 308 are respectivelyformed in the trenches 702 and on the isolation structure liners 306 toform a plurality of isolation structures 210 in the epitaxial structure302. In some embodiments, the isolation structure dielectrics 308 maycomprise an oxide (e.g., SiO₂). In further embodiments, the isolationstructure dielectrics 308 have upper surfaces that are coplanar withupper surfaces of the isolation structure liners 306 and the uppersurface of the epitaxial structure 302.

In some embodiments, a process for forming the isolation structuredielectrics 308 comprises depositing and/or growing (e.g., by CVD, PVD,ALD, thermal oxidation, sputtering, etc.) an isolation structuredielectric layer (not shown) on the isolation structure liners 306 andthe nitride layer of the isolation structure patterning stack 704, suchthat the isolation structure dielectric layer fills the trenches 702.Subsequently, a planarization process (e.g., CMP) is performed on theisolation structure dielectric layer to remove excess portions of theisolation structure dielectric layer. In some embodiments, theplanarization process may expose the nitride layer of the of theisolation structure patterning stack 704. After the planarizationprocess, the nitride layer of the isolation structure patterning stack704 may be stripped away.

As shown in FIG. 9, a pair of first wells 104 are formed in theepitaxial structure 302. The first wells 104 are regions of theepitaxial structure 302 comprising the first doping type (e.g., n-typedoping). In some embodiments, the first wells 104 are formed with alower concentration of the first doping type than the second dopedburied region 114. In some embodiments, the first wells 104 may beformed by a third selective ion implantation process that utilizes amasking layer (not shown) to selectively implant ions into the epitaxialstructure 302. In further embodiments, the third ion implantationprocess may comprise implanting a dosage of phosphorous ions betweenabout 1.0×10¹² ions/cm² and about 8.0×10¹² ions/cm² into the epitaxialstructure 302 at an ion energy between about 2200 keV and about 2800keV.

Also shown in FIG. 9, a pair of first pick-up wells 204 are formed inthe epitaxial structure 302. The pick-up wells 204 are regions of theepitaxial structure 302 comprising the second doping type (e.g., p-typedoping). In some embodiments, the pick-up wells 204 respectively contactthe second doped buried region 114 and the first wells 104. In someembodiments, the pick-up wells 204 may be formed by a fourth selectiveion implantation process that utilizes a masking layer (not shown) toselectively implant ions into the epitaxial structure 302. In furtherembodiments, the fourth ion implantation process may comprise implantinga dosage of boron ions between about 1.0×10¹² ions/cm² and about5.0×10¹² ions/cm² into the epitaxial structure 302 at an ion energybetween about 400 keV and about 800 keV.

As shown in FIG. 10, a second well 108 is formed in the epitaxialstructure 302 between the first wells 104. The second well 108 is aregion of the epitaxial structure 302 comprising the second doping type(e.g., p-type doping). In some embodiments, the second well 108 may beformed with a higher concentration of the second doping type than thefirst pick-up wells 204. In further embodiments, the second well 108 maybe formed laterally spaced from the first wells 104. In yet furtherembodiments, a photodetector 118 comprises the first wells 104, thesecond well 108, and the second doped buried region 114.

In some embodiments, the second well 108 may be formed by a fifthselective ion implantation process that utilizes a masking layer (notshown) to selectively implant ions into the epitaxial structure 302. Infurther embodiments, the fifth ion implantation process may compriseimplanting a dosage of boron ions between about 1.0×10¹³ ions/cm² andabout 1.0×10¹⁴ ions/cm² into the epitaxial structure 302 at an ionenergy between about 1000 keV and about 2000 keV. In furtherembodiments, a second drive-in anneal (e.g., RTA, furnace anneal, etc.)may be performed on the semiconductor substrate 102 to activate the ionsimplanted by the third, fourth, and/or fifth selective ion implantationprocess(es). In yet further embodiments, the second drive-in anneal maycomprise heating the first semiconductor material layer 304 in a N₂environment to a temperature between about 800° C. and about 1200° C.for about 30 minutes to about 120 minutes.

As shown in FIG. 11, a pair of third wells 202 are formed in theepitaxial structure 302. The third wells 202 are regions of theepitaxial structure 302 comprising the first doping type (e.g., n-typedoping). In some embodiments, the third wells 202 are respectivelyformed in the first wells 104. In some embodiments, the third wells 202are formed with a higher concentration of the first doping type than thefirst wells 104. In further embodiments, third wells 202 may be formedby a sixth selective ion implantation process that utilizes a maskinglayer (not shown) to selectively implant ions into the epitaxialstructure 302.

Also shown in FIG. 11, a pair of second pick-up wells 206 are formed inthe epitaxial structure 302. The second pick-up wells 206 are regions ofthe epitaxial structure 302 comprising the second doping type (e.g.,p-type doping). In some embodiments, the second pick-up wells 206 arerespectively formed in the first pick-up wells 204. In some embodiments,the second pick-up wells 206 are formed with a higher concentration ofthe second doping type than the first pick-up wells 204. In furtherembodiments, the second pick-up wells 206 may be formed by a seventhselective ion implantation process that utilizes a masking layer (notshown) to selectively implant ions into the epitaxial structure 302.

As shown in FIG. 12, a pair of first electrodes 106 are formed in theepitaxial structure 302. The first electrodes 106 are regions of theepitaxial structure 302 comprising the first doping type (e.g., n-typedoping). In some embodiments, the first electrodes 106 are respectivelyformed in the third wells 202. In further embodiments, the firstelectrodes 106 may be formed with a higher concentration of the firstdoping type than the third wells 202. In yet further embodiments, thefirst electrodes 106 may be formed by an eighth selective ionimplantation process that utilizes a masking layer (not shown) toselectively implant ions into the epitaxial structure 302.

Also shown in FIG. 12, a second electrode 110 and a pair of pick-up wellcontacts 208 are formed in the epitaxial structure 302. The secondelectrode and the pick-up well contacts 208 are regions of the epitaxialstructure 302 comprising the second doping type (e.g., p-type doping).In some embodiments, the second electrode 110 may be formed with ahigher concentration of the second doping type than the second well 108.In some embodiments, the pick-up well contacts 208 may be formed with ahigher concentration of the second doping type than the second pick-upwells 206. In further embodiments, the second electrode 110 and thepick-up well contacts 208 may be formed by a ninth selective ionimplantation process that utilizes a masking layer (not shown) toselectively implant ions into the epitaxial structure 302. In otherembodiments, the second electrode 110 and the pick-up well contacts 208may be formed by individual ion implantation process(es) that utilizeindividual masking layers (not shown). In yet further embodiments,silicide structures (not shown) (e.g., nickel silicide, titaniumsilicide, cobalt silicide, etc.) may be formed on the first electrodes106, the second electrode 110, and/or the pick-up well contacts 208 by asuitable silicide process (e.g., a salicide process).

As shown in FIG. 13, an interlayer dielectric (ILD) layer 212 is formedon the epitaxial structure 302. In some embodiments, the ILD layer 212comprises one or more layers of a low-k dielectric layer, an ultra-low-kdielectric layer, an oxide, or the like. In further embodiments, the ILDlayer 212 may be deposited by, for example, CVD, ALD, sputtering, or thelike. In yet further embodiments, a planarization process (e.g., CMP)may be performed on the ILD layer 212 to form a substantially planarupper surface.

Also shown in FIG. 13, conductive contacts 214 are formed in the ILDlayer 212. In some embodiments, a process for forming the conductivecontacts 214 comprises performing a first etch into the ILD layer 212 toform contact openings that correspond to the conductive contacts 214. Insome embodiments, the etch may be performed with a masking layer (notshown) formed over the ILD layer 212. In further embodiments, theprocess comprises filling the contact openings with a conductivematerial (e.g., tungsten). In yet further embodiments, the contactopenings may be filled by depositing or growing (e.g., by CVD, PVD, ALD,sputtering, electrochemical plating, electroless plating, etc.) aconductive layer covering the ILD layer 212 that fills the contactopenings, and subsequently performing a planarization process (e.g.,CMP) on the ILD layer 212. In various embodiments, the process may bepart of a single damascene like process or a dual damascene likeprocess.

As shown in FIG. 14, an inter-metal dielectric (IMD) layer 216 is formedon the ILD layer 212. In some embodiments, the IMD layer 216 comprises,for example, a low-k dielectric layer, an ultra-low-k dielectric layer,or an oxide. In some embodiments, the IMD layer 216 may be deposited orgrown on the ILD layer 212 by, for example, CVD, PVD, ALD, sputtering,or the like. In further embodiments, a planarization process (e.g., CMP)may be performed on the IMD layer 216 to form a substantially planarupper surface.

A plurality of conductive features 218 (e.g., conductive lines andconductive vias) are formed in the IMD layer 216. In some embodiments, aprocess for forming the conductive features 218 comprises performing anetch into the IMD layer 216 to form conductive feature openings. In someembodiments, the etch may be performed with a masking layer (not shown)formed over the IMD layer 216. In some embodiments, the processcomprises filling the conductive feature openings with a conductivematerial (e.g., copper, aluminum, etc.). In further embodiments, theconductive feature openings may be filled by depositing or growing(e.g., by CVD, PVD, ALD, sputtering, electrochemical plating,electroless plating, etc.) a conductive layer covering the IMD layer 216that fills the conductive feature openings, and subsequently performinga planarization (e.g., CMP) on the IMD layer 216. In yet furtherembodiments, multiple IMD layers 216 each having a plurality ofconductive features 218 disposed in the IMD layers 216 may be formedstacked on the ILD layer 212. In such embodiments, about 4 to about 10IMD layers 216 may be stacked on the ILD layer 212 to reduce lightattenuation caused by multiple IMD layers 216 and the respectiveconductive features 218 disposed in the IMD layers 216.

Also shown in FIG. 14, a passivation layer 220 is formed on the IMDlayer 216 and some of the conductive features 218. In some embodiments,the passivation layer 220 may comprise, for example, an oxide, anitride, an oxy-nitride, a polymer, or the like. In further embodiment,the passivation layer 220 may be formed by CVD, PVD, ALD, sputtering, aspin on process, or the like. In yet further embodiments, aninterconnect structure 222 comprises the ILD layer 212, the conductivecontacts 214, the IMD layer 216, the conductive features 218, and thepassivation layer 220.

As shown in FIG. 15, a micro-lens 310 is formed on the passivation layer220. In some embodiments, the micro-lens 310 may be formed by depositing(e.g., by a spin-on method or a deposition process) a micro-lensmaterial on the passivation layer 220. A micro-lens template (not shown)having a curved upper surface is patterned on the micro-lens material.In further embodiments, the micro-lens template may comprise aphotoresist material exposed using a distributing exposing light dose(e.g., for a negative photoresist more light is exposed at a bottom ofthe curvature and less light is exposed at a top of the curvature),developed and baked to form a rounding shape. In further embodiments,the micro-lens 310 is then formed by selectively etching the micro-lensmaterial according to the micro-lens template. In yet furtherembodiments, the micros-lens 310 may be formed on a back-side of thesemiconductor substrate 102 (e.g., on a side of the semiconductorsubstrate 102 opposite a side of the semiconductor substrate 102 inwhich the interconnect structure 222 is disposed).

As illustrated in FIG. 16, a flowchart 1600 of some embodiments of amethod for forming the CMOS image sensor of FIG. 3 is provided. Whilethe flowchart 1600 of FIG. 16 is illustrated and described herein as aseries of acts or events, it will be appreciated that the illustratedordering of such acts or events is not to be interpreted in a limitingsense. For example, some acts may occur in different orders and/orconcurrently with other acts or events apart from those illustratedand/or described herein. Further, not all illustrated acts may berequired to implement one or more aspects or embodiments of thedescription herein, and one or more of the acts depicted herein may becarried out in one or more separate acts and/or phases.

At 1602, a first doped buried region comprising a first doping type isformed in a first semiconductor material layer. FIG. 4 illustrates across-sectional view of some embodiments corresponding to act 1602.

At 1604, an initial doped buried layer comprising the first doping typeis formed in the first doped buried layer. FIG. 5 illustrates across-sectional view of some embodiments corresponding to act 1604.

At 1606, an epitaxial structure is formed on the first semiconductormaterial layer. FIG. 6 illustrates a cross-sectional view of someembodiments corresponding to act 1606.

At 1608, an anneal is performed on the epitaxial structure and the firstsemiconductor material layer that diffuses ions of the initial dopedburied layer into the epitaxial structure to form a second doped buriedregion disposed over the first doped buried region. FIG. 7 illustrates across-sectional view of some embodiments corresponding to act 1608.

At 1610, isolation structures are formed in the epitaxial structure.FIGS. 7-8 illustrate a series of cross-sectional views of someembodiments corresponding to act 1610.

At 1612, a pair of first wells, a pair of first pick-up wells, a secondwell, a pair of third wells, a pair of second pick-up wells, a pair offirst electrodes, a second electrode, and a pair of pick-up wellcontacts are formed in the epitaxial structure, wherein the second wellcomprises a second doping type opposite the first doping type andcontacts the second doped buried region between the first doped buriedregion and the second electrode. FIGS. 9-12 illustrate a series ofcross-sectional views of some embodiments corresponding to act 1612.

At 1614, an interconnect structure is formed on the epitaxial structure.FIGS. 13-14 illustrate a series of cross-sectional views of someembodiments corresponding to act 1614.

At 1616, a micro-lens is formed on the epitaxial structure. FIG. 15illustrates a cross-sectional view of some embodiments corresponding toact 1616.

In some embodiments, the present application provides a photodetector.The photodetector includes a first well having a first doping typedisposed in a semiconductor substrate, where the first well extends intothe semiconductor substrate from a first side of the semiconductorsubstrate. A second well having a second doping type opposite the firstdoping type is disposed in the semiconductor substrate on a side of thefirst well, where the second well extends into the semiconductorsubstrate from the first side of the semiconductor substrate. A firstdoped buried region having the second doping type is disposed in thesemiconductor substrate, where the first doped buried region extendslaterally through the semiconductor substrate beneath the first well andthe second well. A second doped buried region having the second dopingtype is disposed in the semiconductor substrate and vertically betweenthe first doped buried region and the first well. The second dopedburied region contacts the first well, such that a photodetector p-njunction exists along the second doped buried region and the first well.

In other embodiments, the present application provides a method forforming a photodetector. The method includes forming a first dopedburied region having a first doping type in a semiconductor substrate. Asecond doped buried region having the first doping type is formed in thefirst doped buried region and over the first doped buried region, wherethe second doped buried region is formed with a different concentrationof the first doping type than the first doped buried region. A pair offirst wells having the first doping type are formed in the semiconductorsubstrate, where the first wells are laterally spaced from one another.A second well having a second doping type opposite the first doping typeis formed in the semiconductor substrate and over the second dopedburied region, where the second well is formed between the first wells,and where a bottom of the second well contacts a top of the second dopedburied region such that a photodetector p-n junction exits along thebottom of the second well and the top of the second doped buried region.A pair of first electrodes having the first doping type are formed inthe semiconductor substrate, where the first electrodes are respectivelyformed in the first wells. A second electrode having the second dopingtype is formed in the second well.

In yet other embodiments, the present application provides aphotodetector. The photodetector includes a pair of first wells having afirst doping type disposed in an epitaxial structure. The first wellsare laterally spaced from one another. The epitaxial structure isdisposed on a first semiconductor substrate. A second well having asecond doping type opposite the first doping type is disposed in theepitaxial structure between the first wells. A pair of cathodes aredisposed in the epitaxial structure, where the cathodes are respectivelydisposed in the first wells. An anode is disposed in the second well. Afirst doped buried region having the first doping type is disposed inthe first semiconductor material layer, where the first doped buriedregion extends laterally through the first semiconductor material layerbeneath the pair of cathodes and the anode. A second doped buried regionhaving the first doping type is disposed in the epitaxial structure andthe first semiconductor material layer between the first doped buriedregion and the second well, where the second doped buried region has alower concentration of the first doping type than the first doped buriedregion. The second doped buried region contacts the second well, suchthat a photodetector p-n junction exists along the second doped buriedregion and the second well.

The foregoing outlines features of several embodiments so that thoseskilled in the art may better understand the aspects of the presentdisclosure. Those skilled in the art should appreciate that they mayreadily use the present disclosure as a basis for designing or modifyingother processes and structures for carrying out the same purposes and/orachieving the same advantages of the embodiments introduced herein.Those skilled in the art should also realize that such equivalentconstructions do not depart from the spirit and scope of the presentdisclosure, and that they may make various changes, substitutions, andalterations herein without departing from the spirit and scope of thepresent disclosure.

What is claimed is:
 1. A photodetector, comprising: a first wellcomprising a first doping type disposed in a semiconductor substrate,wherein the first well extends into the semiconductor substrate from afirst side of the semiconductor substrate; a second well comprising asecond doping type opposite the first doping type disposed in thesemiconductor substrate and on a side of the first well, wherein thesecond well extends into the semiconductor substrate from the first sideof the semiconductor substrate; a first doped buried region comprisingthe second doping type disposed in the semiconductor substrate, whereinthe first doped buried region extends laterally through thesemiconductor substrate beneath the first well and the second well; asecond doped buried region comprising the second doping type disposed inthe semiconductor substrate and vertically between the first dopedburied region and the first well, wherein the second doped buried regioncontacts the first well such that a photodetector p-n junction existsalong the second doped buried region and the first well; and a pick-upwell comprising the first doping type disposed in the semiconductorsubstrate and laterally separated from the first well by the secondwell, wherein the pick-up well contacts the second well and the seconddoped buried region, wherein a side of the pick-up well facing the firstwell continuously contacts the second well, the second doped buriedregion, and the first doped buried region.
 2. The photodetector of claim1, wherein the second doped buried region has a different concentrationof the second doping type than the first doped buried region.
 3. Thephotodetector of claim 2, wherein the second doped buried region has alower concentration of the second doping type than the first dopedburied region.
 4. The photodetector of claim 1, further comprising: anisolation structure disposed over the second doped buried region andbetween the second well and the pick-up well.
 5. The photodetector ofclaim 4, wherein the isolation structure is vertically spaced from thesecond doped buried region.
 6. The photodetector of claim 5, wherein theside of the pick-up well facing the first well vertically extends fromthe second doped buried region to a bottom surface of the isolationstructure.
 7. The photodetector of claim 6, further comprising: a firstelectrode comprising the first doping type disposed in the first well; asecond electrode comprising the second doping type disposed in thesecond well, wherein the second electrode is laterally spaced from thefirst electrode; and a third well comprising the second doping typedisposed in the second well separating the second electrode from thesecond well, wherein the second well separates the third well from thesecond doped buried region.
 8. A photodetector, comprising: a pair offirst wells comprising a first doping type disposed in an epitaxialstructure, wherein the first wells are laterally spaced, and wherein theepitaxial structure is disposed on a first semiconductor material layer;a second well comprising a second doping type opposite the first dopingtype disposed in the epitaxial structure and between the first wells; apair of cathodes disposed in the epitaxial structure, wherein thecathodes are respectively disposed in the first wells; an anode disposedin the second well; a first doped buried region comprising the firstdoping type disposed in the first semiconductor material layer, whereinthe first doped buried region extends laterally through the firstsemiconductor material layer beneath the pair of cathodes and the anode;a second doped buried region comprising the first doping type disposedin the epitaxial structure and the first semiconductor material layerand disposed between the first doped buried region and the second well,wherein the second doped buried region has a lower concentration of thefirst doping type than the first doped buried region, and wherein thesecond doped buried region contacts the second well such that aphotodetector p-n junction exists along the second doped buried regionand the second well; and a first pick-up well comprising the seconddoping type disposed in the epitaxial structure and separated from thesecond well by a first one of the first wells, wherein a side of thefirst pick-up well facing the second well continuously contacts thefirst one of the first wells, the second doped buried region, and thefirst doped buried region.
 9. The photodetector of claim 8, wherein thefirst wells are respectively spaced from opposite sides of the secondwell, and wherein each of the first wells contact the second dopedburied region.
 10. The photodetector of claim 8, wherein the seconddoped buried region contacts bottoms of the first wells.
 11. Thephotodetector of claim 10, wherein a bottom of the first pick-up well isdisposed below the bottoms of the first wells.
 12. A photodetector,comprising: a pair of first wells having a first doping type disposed ina semiconductor substrate, wherein the first wells are laterally spaced;a second well having a second doping type opposite the first doping typedisposed in the semiconductor substrate and between the first wells; apair of first electrodes having the first doping type disposed in thesemiconductor substrate, wherein the first electrodes are disposed inthe first wells, respectively; a second electrode having the seconddoping type disposed in the second well and between the firstelectrodes; a first doped buried region having the first doping typedisposed in the semiconductor substrate, wherein both of the first wellsat least partially overlie the first doped buried region; a second dopedburied region having the first doping type disposed in the semiconductorsubstrate, wherein the second doped buried region is disposed betweenthe first wells and contacts both the second well and the first dopedburied region, and wherein the second doped buried region has a lowerconcentration of first doping type atoms than the first doped buriedregion; and a pair of pick-up wells having the second doping typedisposed in the semiconductor substrate, wherein the pick-up wells aredisposed on opposite sides of the second doped buried region, andwherein a side of a first one of the pick-up wells facing the secondwell continuously contacts a first one of the first wells, the seconddoped buried region, and the first doped buried region.
 13. Thephotodetector of claim 12, wherein: the semiconductor substratecomprises an epitaxial structure disposed over a semiconductor materiallayer, wherein the second doped buried region is disposed in both thesemiconductor material layer and the epitaxial structure.
 14. Thephotodetector of claim 12, wherein both of the first wells at leastpartially overlie the second doped buried region.
 15. The photodetectorof claim 14, wherein: the second doped buried region contacts both ofthe first wells; and the second doped buried region vertically separatesthe first doped buried region from both of the first wells.
 16. Thephotodetector of claim 14, wherein a side of a second one of the pick-upwells continuously contacts a second one of the first wells, the seconddoped buried region, and the first doped buried region.
 17. Thephotodetector of claim 16, wherein the second well is laterally spacedfrom both of the first wells.
 18. The photodetector of claim 8, furthercomprising: a second pick-up well having the second doping type anddisposed in the first pick-up well, wherein the second pick-up well hasa higher concentration of second doping type atoms than the firstpick-up well.
 19. The photodetector of claim 18, wherein the firstpick-up well separates the second pick-up well from the first one of thefirst wells, the second doped buried region, and the first doped buriedregion.
 20. The photodetector of claim 19, wherein a bottom of thesecond pick-up well is disposed vertically between the second dopedburied region and the anode.